Rare-earth solid-state qubits

TL;DR

This paper introduces a new family of rare-earth ion-based spin qubits demonstrating promising coherence times and figures of merit at relatively high temperatures, indicating potential for scalable quantum computing.

Contribution

It reports the discovery of rare-earth solid-state qubits with coherence times and figures of merit suitable for scalable quantum information processing at 2.5 K.

Findings

Tau2 ~ 50 microseconds at 2.5 K

QM ~ 1400 at 2.5 K

Potential scalability for quantum computing

Abstract

Quantum bits (qubits) are the basic building blocks of any quantum computer. Superconducting qubits have been created with a 'top-down' approach that integrates superconducting devices into macroscopic electrical circuits [1-3], whereas electron-spin qubits have been demonstrated in quantum dots [4-6]. The phase coherence time (Tau2) and the single qubit figure of merit (QM) of superconducting and electron-spin qubits are similar -- Tau2 ~ microseconds and QM ~10-1000 below 100mK -- and it should be possible to scale-up these systems, which is essential for the development of any useful quantum computer. Bottom-up approaches based on dilute ensembles of spins have achieved much larger values of tau2 (up to tens of ms) [7, 8], but these systems cannot be scaled up, although some proposals for qubits based on 2D nanostructures should be scalable [9-11]. Here we report that a new family of spin qubits based on rare-earth ions demonstrates values of Tau2 (~ 50microseconds) and QM (~1400) at 2.5 K, which suggests that rare-earth qubits may, in principle, be suitable for scalable quantum information processing at 4He temperatures.